Method of manufacturing a socket for sub-miniature electronic devices



out. 11, 1960 s. wm'rmss 2,955,352 METHOD OF MANUFACTURING A SOCKET FOR SUB-MINIATURE ELECTRONIC DEVICES Filed Oct. 22, 1954 3 Sheets-Sheet 1 IN V EN TOR. 660265 Wl/VTZ/fiS s. wm'rmss 1 2,955,353 METHOD OF MANUFACTURING A SOCKET F'QR SUB-MINIATURE ELECTRONIC DEVICES 3 Sheets-Sheet 2 Filed 061;. 22, 1954 uvmvron 5am; Mme/s BY f a A den/ 75 Oct. 11, 1960 G. WINTRISS 2,955,352

METHOD OF MANUFACTURING A SOCKET FOR SUB-MINIATURE ELECTRONIC DEVICES 5 Sheets-Sheet 3 Filed Oct. 22, 1954 INVENTOR. 550,2 5 W/A/TE/Jfi Patented Oct. 11, 1960 George Wintriss, trial Electronic York Carversville, Pa., assignor to Indus- Hardware 'Corp., a corporation of New Filed Oct. 22, 1954, Ser. No. 463,958 '18 Claims. (Cl. 29-15555 This invention relates to electrical sockets, particularly for electronic devices such as radio tubes, and more especially to sub-miniature tubes, transistors, and the like.

In electronics manufacture there is a strong trend toward miniaturization, including the miniaturization of tubes and the use of transistors which are even smaller. This has led to a corresponding miniaturization of the socket for detachably receiving the prongs of such devices. The primary object of the present invention is to generally improve sockets for receiving the prongs of subminiature electronic devices, and to generally improve the method of manufacture of the same.

A typical socket comprises a molded insulation base having a plurality of passages each holding a metal contact. Heretofore the metal contacts have been made and handled individually, and it. has been a laborious and painstaking task to load the :base with the contacts, the latter often being handled with tweezers. The con tact includes a so-called tail or soldering lug portion, and this has been manually twisted to hold the contact in the base, thus again adding to the labor cost. One form of contact has been stamped in bifurcated shape, out of flat sheet metal. Such flat stamped contacts have been found to quickly lose their retention or grip on the pin inserted therein, after a number of insertions.

Other contacts have been of the so-called single wire type, including a convex spring portion at one end, and a tail at the other. of flat wire, which might seem inexpensive, but these contacts have nevertheless proved to be highly expensive because it is necessary to heat treat and temper the same. Moreover, the contacts are preferably coated with a corrosion-resistant added as a separate operation after heat treatment of the contact.' Such contacts have also had the disadvantage of being too weak at critical points, so that they are not strongly anchored in the base.

The main object of the come the foregoing difficulties and disadvantages, and to provide an improved socket characterized by low cost and good retentivity. The socket is further improved by the provision of large entrant openings to more readily receive the prongs of the sub-miniature tube or other device, because the said prongs are so slender that they are frequently bent or displaced slightly away from proper position.

A further object is to provide an improved manufac- Such contacts have been formed out metal, typically silver, and this must be .1

present invention is to over- I turing process in which single wire contacts are employed,

yet there is no need to heat treat the same. Even more important, there is no need to handle the individual contacts, and instead the operator works with a continuous wire. Moreover, the improved process is of such character that it facilitates a change from manual to complete mechanization or automatic assembly of the socket.

The present application is directedto and claims the manufacturing process' The socket is not claimed herein, it being claimed in my copending divisional application,

Serial No. 537,122, filed September 28, 1955-, now Patent No. 2,855,579.

To accomplish the foregoing general objects, and other more specific objects which will hereinafter appear, my invention resides in the socket elements and manufacturing steps, and their relation one to another, as are hereinafter more particularly described in the following specification. The specification is accompanied by drawings, in which:

Fig. 1 is a front elevation of a flat sub-miniature tube having five prongs;

Fig. 2 is a front elevation of a socket embodying features of my invention, and shows a fragmentary section of a chassis plate receiving the socket;

Fig. 3 is an end elevation of the same;

Fig. 4 is a front elevation, shown to enlarged scale, of a contact of the single wire type, modified inaccordance with my invention;

Fig. 5 is a side elevation of the same;

Fig. 6 is a plan view of the molded insulation base;

Fig. 7 is a section taken approximately in the plane of the line 7--7 of Fig. 6;

Fig. 8 is a horizontal section taken approximately in the plane of the line 88 of Fig. 7, and shows the contacts with and without prongs bearing against the same;

Fig. 9 is a bottom view of the molded insulation base, without contacts;

Fig. 10 shows the rectangular lock ring which anchors the socket in the chassis;

Fig. 11 is a schematic view explanatory of the coining of the continuous series or wire-of-contacts;

Fig. 12 is a perspective view showing the coining operation;

Fig. 13 shows how is inserted in the base the wire; V

Fig. 14 is a perspective view explanatory of the method of bending the tails of the contacts;

Fig. 15 is a schematic view explanatory of the process for fully automatic assembly of the socket;

Fig. 16 is a perspective view, drawn to enlarged scale, at the feed pawls and cutting blades;

Fig. 17 is a side elevation showing how the feed pawls cooperate with stationary rails;

Fig. 18 is a section taken approximately in the plane of the line 18-18 of Fig. 17, but with the upper and lower parts separated for clarity;

Fig. 19 is a vertical section further explanatory of the cutting blades;

Fig. 20 is a partially sectioned fragmentary view explanatory of the mechanism for bending the tails of the contacts; and

Fig. 21 is a schematic plan view of a part of the assembly apparatus shown in Fig. 15.

Referring to the drawing, and more particularly to Fig. 1, I there show a fiat sub-miniature tube 12 having a series of five prongs 14 at its lower end. These prongs are disposed in a plane, rather than a circle, and are relatively thin wires, rather than stiff prongs as in the so-called miniature tubes, which are much larger. I am here describing my invention as applied to a socket having five contacts, but it will be understood that the same improvements and method steps are applicable to sockets having a lesser or greater number of contacts for receiving a lesser or greater number of prongs.

Referring now to Figs. 2 and 3 of the drawing, the socket is there shown drawn to enlarged scale, and comprises having upright passages therethrough receiving metal contacts of the single wire type. The lower ends of the contacts act as tails or soldering lug portions, and these are shown at 18 and 20 in the the end contact of the coined wire before separating the contact from drawing, it being understood that succeeding tails are bent in opposite direction, or, in other words, that alternate tails are bent in the same direction, with the intermediate tails bent in opposite direction.

The socket is secured in a chassis plate 22 by preliminarily forming a rectangular hole in the chassis plate, said hole being dimensioned to receive the body portion of the socket. The socket is dropped down from above, and cannot pass through the chassis because the base is enlarged at the top, as indicated at 24. In the present case there are four such enlargements or projections, as is better shown in Figs. 6 and 7.

The socket is held in the chassis by means of a rectangular retainer ring 26. This is a metal stamping shaped as is best shown in Fig. 10. The rectangular opening 28 within the ring is dimensioned to receive the body portion 16 of the insulation base. However, there are a pair of inwardly projecting fingers 30 dimensioned to be received in recesses 32 formed at the sides of the base. The center portion of ring 26 is bowed downward, as shown in Fig. 2 except that the initial bend is even greater than there shown. It will be understood that after the socket has been inserted in the chassis the ring 26 is forced upward from beneath, and is partially flattened during this operation until the locking tabs 30 snap into the recesses 32, thus anchoring the socket securely on the chassis. To insure proper orientation of the socket when inserting the same in the chassis, and even earlier when loading the base with contacts, the base may be provided with a small projection or pin 34 located in one corner.

The contact used in the socket is shown in Figs. 4 and 5, which are drawn to even larger scale. The contact comprises a convex spring portion 40, a stop portion 42 located at the lower end of the spring portion 40, and a tail or soldering lug portion 44. The spring portion 40 is preferably of flat section, and the same applies to the tail portion 44. The stop portion 42 is preferably narrower and thicker than the rest of the contact. The contact is preferably made of a resilient and highly conductive material, for example, beryllium copper, and is preferably coated with a corrosion-resistant coating, for example silver. In a typical case the flat portions 40 and 44 have a thickness of and a width about three times the thickness, whereas the stop portion 42 has a thickness around the bend 46 of and a much greater thickness at the upper part 42 of the bend,

The location of the contact within the base will be understood from inspection of Fig. 7 of the drawing. The main part of the passage through the base is shown at 48. This receives the convexed or spring portion 40 of the contact. It will be understood that the initial convexity is greater than that permitted in passage 48, so that the spring portion is somewhat flattened and preloaded, even before insertion of a tube prong. Downward movement of the contact is limited by the relatively thick and rigid stop portion 42, which bears against a preferably sloping ledge 50 near the lower end of passage 48. The tail portion 44' .nitially projects below the base 16 as shown in broken lines, but is bent to provide a shoulder 52 and a soldering lug portion 44. Thus the contact is anchored against upward movement, as when a tube is withdrawn from the socket.

It will be understood that successive contacts are reversed in direction, that is if one contact is convex toward the right, as shown in Fig. 7, the immediately adjacent contact on either side will be convex toward the left. Therefore the passage 54 is offset relative to the passage 48, and referring to Fig 9, which shows the five narrow or rectangular tail passages like the passage 54, it will be seen that three of the passages are displaced downward, while the intermediate two passages are displaced upwardand this, of course, corresponds to the reversal of the position of the contacts in the base.

7 Referring now to Figs. 6 and 7, it may be explained that the passages 48 are divergently enlarged at their upper ends to more readily receive the tube prongs. The

. trant passages of maximum size divergent nature of this enlargement will be seen at 56 and 58 in Fig. 7, and in Fig. 6 it will be seen that the entrant end of each passage becomes a pentagon which is nearly triangular. The succeeding triangles are reversed in position so that the intermediate triangles fit between the alternate triangles, and the material left between triangles is reduced to a sharp edge, thus making the endespite the close spacing of the prongs. In Fig. 6 the upper-most end 78 only of each contact is shown, in order not to confuse or obscure the showing of the enlargement of the passages at the upper end, and the upper end of the contact is marked by vertical hatching. This is sufficient to show the alternating or reversed positioning of adjacent contacts.

Referring now to Fig. 8 of the drawing, the main body 48 of the passage through the base is a six-sided figure in which three sides form a rectangle dimensioned to receive the contact spring 40, while the remaining three sides form a trapezoidal portion too small to receive the spring. In the absence of tube prongs the passages and springs assume a position somewhat as shown in the three lefthand passages, it being understood that the spring 40 is attempting to move upward; that the next spring is attempting to move downward; and that the next spring is attempting to move upward, and so on. When a tube is inserted, its prongs displace or flatten the springs somewhat, as shown by the prongs 60 and 62. The prong 60 flattens its spring upward, and similarly the prong 62 flattens its spring downward. Of course, in practice all five prongs are inserted at once, and the showing in Fig. 8 is frictional in that respect. Also the prong diameter has been exaggerated in Fig. 8, and in practice the prongs all lie in one plane when inserted in the socket.

The method of making my improved socket may be described with preliminary reference to Fig. 11. A reel 64 of wire is provided, and the wire 66 is fed through a suitable apparatus 68 for coining the same to form or shape the contacts. However, the contacts are not severed from one another, and instead remain connected end-toend to form a continuous series or chain of connected contacts 70, which could be utilized as they leave the coining mechanism 68, but which more conveniently are reeled up on a reel 72 for later use. When the contact wire is reeled as here shown, the contacts are preferably coined and reeled with the spring portions leading the tail portions, so that subsequently they may be unreeled for use with the tail portions foremost.

The coining operation is shown in schematic perspective in Fig. 12. The wire 66 is initially a round wire, and it is generally flattened by the coining operation. This has the advantage of work hardening the material, and thereby imparting increased resilience to the material, without requiring heat treatment. For this purpose the wire 66 need not necessarily be a round wire, the only requirement being that it be initially narrower and thicker than the finished contacts, but a round wire is most commonly available and least expensive, and the ability to use a round wire is one of the advantages of my process. In the specific case here shown the wire is initially a round wire having a diameter of 0.020".

The coining dies 74 and 76 serve to not only flatten the wire but also to form the desired convexity 40 for the spring portion, and the reverse bend 46 at the stop portion. It will be understood that the contact is narrower and thicker at the part 46, and particularly thick at the leading end of this part corresponding to the part 42 in Figs. 5 and 7. This increased thickness is important in order to provide a positive or solid stop against downward movement of the contact when a prong is inselted, and also helps increase the resilience or spring action of the contact by giving it a somewhat cantilever action about its lower end.

Finally, the coining operation preferably includes a notching and consequent weakening of the wire between one contact and the next. This is best shown at 78 in Fig. 13, in which it will be seen that the lower end or tip of tail 44 is beveled immediately adjacent the upper end of spring portion 40 of the adjacent contact, thus providing a necked or weakened connection between the two. This facilitates subsequent separation of the individual contacts. In the specific case here shown the thickness at the break-01f point is about 0.006, particularly for hand loading, whereas the thickness of the tail is 0.011 as previously mentioned.

The socket may be assembled by a method next described with reference to Fig. 13 of the drawing. The operator has'at hand a supply of the molded bases 16, and a reel of contact wire. The wire is fed tail foremost through a passage 48 in the socket until the contact assumes the position shown in Fig. 13, whereupon thesocket and wire are bent relative to one another to break the wire at the point 78. The tail portion 44' is next inserted into another passage of the base and the contact broken free, and so on until the passages are filled. In practice the operator will ordinarily first fill the three alternate passages in which the wire faces one way, and thereupon turn the base over (or twist the wire) to fill the remaining two intermediate passages. The orientation pin 34 previously referred to (Figs. 2, 3 and 6) helps the operator know which way to insert the wire, by a sense of touch alone, and without having to study the base after selecting one from a pile.

When the base has been loaded with the contacts the socket is complete except for bending of the tails. These rnay be individually bent, or individually twisted, but I prefer to bend all five tails at once, and for this purpose I provide a fixture comprising two guide blades 80 (Fig. 14) and 82, and a forming blade 84. The blade 84 moves horizontally towards the socket and spreads the tails apart. Such a blade might alone be sufiicient to bend the tails, but it is preferred not to work directly against the insulation material of the base. For this reason the guides 80 and 82 are provided. The lower edge of guide 80 reaches the top tails, and the upper edge of guide 82 reaches the bottom tails. These edges receive the force of the bending blade 84 when it moves toward the socket, thus bending all five'tails at once, and without subjecting the insulation material to any breaking strain.

As so far described the assembly operation is partially manual and partially mechanized, but my present improvement in which the contacts are kept connected end-to-end in a continuous wire greatly facilitates complete mechanization of the assembly operation, by a method next described. Referring to Fig. 15, I provide five reels of contact wire 86, 88, fit}, 92 and 94. The contact wire is drawn from the top of three of the reels 86,90, 94, while the other two reels 88 and 92 are reversed and the contact wire is drawn from the bottom thereof, in order to suitably orient the five wires relative to the base of the socket. The five wires are fed toward an assembly station in'an apparatus 96 by five feed pawls, two of which are schematically indicated at 28 and 109. The molded bases are poured into a suitable hopper 102, and are sorted and fed downward in uniform orientation by conventional rotating hopper meansindicated at 104. The sockets descend to a horizontal track where they are moved end to end in a direction transverse to the drawing.

Referring now to Fig. 16 it will be seen how three upper pawls 106, 108, 110 bear against the three lower wires 112, 1 14, 1 16'while at the same time two lower pawls 118 and 120 bear against two upper wires 122, 124, thus feeding five wires at once into a single base 16. In practice the wires are supported on the side opposite the pawls, as shown in Fig. 17,and for this purpose narrow rails may be provided, there being three such rails 126, 128 and 130 (Fig. 18) beneath the three lower wires 112, 114 and 116 to receive the force of the three upper pawls 106, 108 and 110, and there vbeing two 3 upper rails 132 and'134 above the two upper wires 122, 1 124 to receive the force of the two lower pawls 118 and 120. The lower pawls are reciprocated between the 170 and 172.

guides and 82 in Fig. 14. The

lower stationary rails, reciprocated between contacts are preferably severed rather than broken from the continuous wire. tion of the contacts For this purpose the initial inseris preferably made slightly incomplete at the time of the severing operation, because the contacts are severed l y oppositely moved vertical cutting blades 140, 142 Fig. 16). One of these, in this case the blade 142, is disposed adjacent the top face of the insulation base 16. The other blade is: displaced slightly and comes into shearing action with the blade 142, as shown in Fig. 19. Thus no strain is placed on the insulation material. In order that all five wires be cut simultaneously the blades are preferably notched or castellated, as is best shown in Fig. .16. Thus the parts 144, 146 and 148 of blade 140 which are to cut the lower I three wires, pass between and around the upper two wires, and similarly the parts 150 and 152 of blade 142, which cut the upper two wires, pass between the lower three wires. Of course, the advance parts ef blade 140 cooperate with the notched parts of blade 142, and similarly the advance parts of blade 142 cooperate with the notched parts of blade 140. The depths of the notches preferably correspo nd to the normal vertical spacing between the upper and lower wires at the parts therealong which are to be severed, so that all five wires are simultaneously severed without significant displacement or bending of the wires.

To complete the insertion of the contacts it is merely necessary to bear against the five short projecting ends, thus moving them inward until they no longer protrude from the top of the insulation base.

Referring to Fig. 20, the sockets 16 are moved through a guide track formed by upper and lower guide members These include edge portions at the bottom end of the base against which the tails are bent by a horizontal bending punch 174. The punch corresponds to the part 84 in Fig. 14, and the guide edges against which the tails are bent correspond to the edges of the top end of base 16 is held by rail portions 176 and 178. Immediately ahead of the bending operation a pusher finger 1% moves to the right to finish the insertion of the contact. There are five such fingers for the five contacts, and all move simultaneously. In fact, a single member 180 maybe used for all five contacts, the end of this member being provided with three lower projections and two upper projections in appropriate staggered relation to bear against the ends of the five contacts and thus finish the insertion of the same. A lower projection is shown in solid lines and an upper projection is shown in dotted lines.

If desired the contacts may be preliminarily moved inward from the position shown in Fig. 19, until they are flush with the top of the base, and this may be done by a sloping guide wall which converges toward the top of the base and which acts as a plow against which the ends of the contacts bear as the base is moved along its guide track from one station to the next. When it isdesired that the upper ends of the contacts be disposed somewhat below the top of the base, as here shown in Figs. 7 and 13 of the drawing, it is the pusher 180 which then serves to complete the insertion of the contacts;

Referring now to Fig. 21 of the drawing,'this is a highly schematic plan view of the assembly apparatus 96 previously shown in Fig. 15. The part 102 represents the hopper for receiving the insulation bases. The five wires coming into the apparatus from the five reels are indicated at 154. The feed dogs are located at 166. The track or path along which the insulation bases are moved edge to edge (as in Fig. 16) is indicated at 156. The station for inserting and severing the wires is immediately at the ends of the wires 154. The bending of the ,tails is accomplished at a subsequent station designated 158. Prior to this operation the severed contacts may be further inserted until flush, at station 159, and then simultaneous with the said tail bending operation the insertio'n of the contacts may be completed by means indicated at 160. The station 159 may be simply a sloping wall against which the projecting ends of the contacts bear, the said wall converging toward the top of the base. The completed sockets fall down a chute 162 into a suitable box or container 164.

It is believed that my improved socket for subminiature tubes and like electronic devices, and the method of manufacture of the same, as well as the advantages thereof, will be apparent from the foregoing detailed description. The tube prongs are readily inserted in the socket because of the large entrant openings, which occupy the entire available space. In fact, the plastic material left between adjacent openings is reduced to a sharp edge. The contacts are of the single wire type, but have a good spring action, without requiring heat treatment. This results from the cold working, and from the variable thickness of the material. The usual specified retention force for a single contact on a single prong is /2 oz. The present contact has an initial retention of 5 02., and even after indefinitely prolonged insertion and removal of a prong the drop in retention at most is to 2 /2 02., which still is five times the specified requirement.

Each contact is securely locked in the base by a heavy stop at the inside, and a bent shoulder at the bottom. The contacts are coated with a non-corrosive coating, but at minimum expense because the wire initially used is coated, and the coining operation does not destroy the coating. The contacts, although tiny, need not be handled individually, and instead are handled as a part of a continuous wire, thus greatly facilitating manual loading of contacts into the base, and also making feasible fully automatic loading. All of the contacts required for a single socket may be loaded simultaneously, and all of the tails may be bent simultaneously, thus greatly speeding the manufacture of the socket.

It will be understood that while I have shown and described the invention in a preferred form, changes may be made without departing from the scope of the invention, as sought to be defined in the following claims.

I claim:

1. In the manufacture of a socket for subminiature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a continuous wire to form a series of contacts connected end to end, inserting the contacts endwise in the base tail foremost, and separating the wire from an inserted contact after the contact has been inserted in the base.

2. In the manufacture of a socket for subminiature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single Wire type, the method which includes coining a continuous wire to form a series of contacts connected end to end, reeling the coined wire head foremost for subsequent utilization, unreeling the coined wire and inserting the contacts endwise in the base tail foremost, and separating the wire from an inserted contact after the contact has been inserted in the base.

3. In the manufacture of a socket for subminiature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, themethod whichincludes coining a. continuous wire to form a series of contacts connected end to end, reeling the coined wire head foremost for subsequent utilization, unreeling the coined wire and inserting the contacts endwise in the base tail foremost, separating the wire from an inserted contact after the contact has been inserted in the base, and bending the projecting tail of the contact to anchor the contact in position.

4. In the manufacture of a socket for subminiature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a continuous wire to form a connected series of contacts, during the coining operation notching and weakening the wire between the tail of one contact and the spring portion of the next succeeding contact, inserting a first contact in a first passage, bending the base relative to the wire to break the contact from the wire, inserting a second contact in a second passage and again breaking said contact from said wire, and so on until all of the passages have been loaded with contacts, whereby the contacts need not be individually handled during the loading operation.

5. In the manufacture of a socket for subminiature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a continuous wire to form a connected series of contacts, during the coining operation notching and weakening the wire between the tail of one contact and the spring portion of the next succeeding contact, reeling the coined wire for subsequent utilization, unreeling the coined wire tail foremost, inserting a first contact in a first passage, bending the base relative to the Wire to break the contact from the wire, inserting a second contact in a second passage and again breaking said contact from said wire, and so on until all of the passages have been loaded with contacts, whereby the contacts need not be individually handled during the loading operation, and finally bending the projecting tails of the contacts to anchor same in position.

6. In the manufacture of a socket for subminiature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a plurality of continuous wires to form a plurality of connected series of contacts, said contacts being connected end to end there being as many such series as there are passages in the base, simultaneously feeding all of the wires tail foremost into all of the passages of a single base, separating all of the inserted contacts from the wires, replacing said base with another base, and again simultaneously inserting all of the endmost contacts into the passages of said second base, and thereafter separating the inserted contacts from said wires.

7. In the manufacture of a socket for subminiature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a continuous wire to form a connected series of contacts, said contacts being connected end to end reeling the coined wire head foremost for subsequent utilization, preparing as many such reels as there are passages in the base, simultaneously unreeling all of the wires tail foremost from all of said reels, and feeding the endmost contacts simultaneously into all of the passages of a single base separating all of the inserted contacts from the Wires, replacing said base with another base, and inserting all of the endmost con- 5 and thereagain simultaneously tacts into the passages of said second base, after separating the inserted contacts from said wires.

8. In the manufacture of a socket for sub-miniature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining acontinuous wire to form a connected series of'contacts,

said contacts .being connected end to end reeling the coined wire head foremost for subsequent utilization, preparing as many such reels as there are passages in the base, simultaneously unreeling all of the wires tail foremost from all of said reels, and feeding the endmost contacts simultaneously into all of the passages of ,a single base, separating all of the inserted contacts from the wires, replacing said base with another base, and again simultaneously inserting all of the endmost contacts into the passages of said second base, and thereafter separating the. inserted contacts from said wires, and finally simultaneously bending the projecting tails of the contacts of a base to anchor the contacts in the base.

9. In the manufacture of a socket for sub-minature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a continuouswire to form a connected series of contacts, said contacts being connected end to end during the coining operation notching and weakening the wire between the tail of one contact and the spring portion of the next succeeding contact, reeling the coined wire head foremost for subsequent utilization, preparing as many such reels as there are passages in the base, simultaneously unreeling all of the wires tail foremost from all of said reels, and feeding the endmost contacts simultaneously into all of the passages of a single base, separating all of the inserted contacts from the wires at the notches, replacing said base with another base, and again simultaneously inserting all of'the endmost contacts into the passages of said second base, and thereafter separating the inserted contacts from said wires at the notches.

10. In the manufacture of a socket for sub-miniature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a plurality of continuous wires to form a plurality of connected series of contacts, said contacts being connected end to end simultaneously feeding a plurality of said wires tail foremost into a plurality of the passages of a single base, separating the inserted contacts from the wires, replacing said base with another base, and again simultaneously inserting a plurality of the endmost contacts into a plurality of the passages of said second base, and thereafter separating the inserted contacts from said w1res.

11. In the manufacture of a socket for sub-miniature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includescoining a continuous wire to form a connected series of contacts,

said contacts being connected end to end reeling the coined wire head foremost a for subsequent utilization, preparing a plurality of such reels, simultaneously unreeling a plurality of the wires tail foremost from a plurality of said reels, and feeding the endmost contacts simultaneously into a plurality of the passages of a single base, separating the inserted contacts from the wires, replacing said base with another base, and again simultaneously inserting a plurality of the endmost contacts into a plurality of the passages of said second base, and thereafter separating the inserted contacts from said wires.

12. In the manufacture of a socket for sub-miniature electronic devices, said socket comprising a molded insulation base having passages receiving metal contacts of the single wire type, the method which includes coining a continuous wire to form a connected series of contacts, said contacts being connected end to end reeling the coined wire head foremost for subsequent utilization, preparing a plurality of such reels, simultaneously unreeling a plurality of the wires tail foremost from a plurality of said reels, and feeding the endmost contacts simultaneous- -ly into a plurality of the passages of a single base, separating the inserted contacts from the wires, replacing said base with another base, and again simultaneously inserting a plurality of the endmost contacts into a plurality of the passages of said second base, and thereafter separating the inserted contacts from said wires, and finally simultaneously bending the projecting tails of the contacts of a base to anchor the contacts in the base.

13. In the manufacture of a socket for sub-miniature electronic devices, said socket comprising a-molded insulation base with passages receiving spring metal contacts of the single wire type, the method which includes recurrently coining and thereby flattening recurrent portions of a long continuous slender wire in order to work harden and thereby impart increased resilience to the contact without heat treatment of the wire, said coining operation being so performed as to also shape the recurrent contacts end to end to provide a convex spring portion of fiat section, a relatively straight tail portion of fiat section, and an intermediate stop portion of decreased width and increased thickness, said stop portion being laterally offset from said spring and tail portions, inserting the contacts tail foremost in the base, and separating the wire from an inserted contact after the contact has been inserted in the base.

14. In the manufacture of sockets for subminiature electronic devices, said sockets comprising a molded insulation base with passages receiving spring metal contacts of the single wire type, the method which includes recurrently coining and thereby flattening recurrent portions of a long continuous slender wire in order to work harden and thereby im art increased resilience to the contact without heat treatment of the wire, said coining operation being so performed as to also shape the contact to provide a convex spring portion of flat section, a relatively straight tail portion of fiat section, and an intermediate stop portion of decreased width and increased thickness, said stop portion being laterally offset from said spring and tail portions, repeating said coining operation along a continuous wire to form contacts connected end to end, reeling the resulting continuous series of connected contacts, preparing a plurality of such reels,

simultaneously unreeling a plurality ofthe wires tail contacts into a plurality of the passages of said second base, and thereafter separating the inserted contacts from said Wires, and so on. v

15. In the manufacture of sockets for subminiature electronic devices, said sockets comprising a molded insulation base with passages receiving spring metal contacts of the single wire type, the method of making said contacts which includes coating with a corrosion resistant metal a round wire made of a metal which is'both resilient and highly conductive, cold coining and thereby flattening recurrent portions of the wire in order to work harden and thereby impart increased resilience to the contact without heat treatment of the Wire, said coining operation being so performed as to also shape the contact to provide the desired contact configuration for use in the socket, and repeating said coining operation along a continuous wire to form contact-s connected end to end.

16. In the manufacture of sockets for subminiature electronic :devices, said sockets comprising a molded insulation base with passages receiving spring metal contacts of the single wire type, the method of making said contacts which includes coating with a corrosion resistant metal a round wire made of a metal which is both resilient and highly conductive, cold coining and thereby flattening recurrent portions of the wire in order to work operation being so performed as to also shape the contact to provide a convex spring portion of flat section, a relatively straight tail portion of flat section, and an intermediate stop portion of decreased width and increased thickness, said stop portion being laterally offset from said spring and tail portions, and repeating said coining operation along a continuous wire to form contacts connected end to end.

17. In the manufacture of sockets for subminiature electronic devices, said sockets comprising a molded insulation base with passages recei 'ng spring metal contacts of the single wire type, the method of making said contacts which includescoating with a corrosion resistant metal a round wire made of a metal which is both resilient and highly conductive, cold coining and thereby flattening recurrent portions of the Wire in order to Work harden and thereby impart increased resilience to the contact without heat treatment of the wire, s aid coining operation being so performed as to also shape the contact to provide a convex spring portion of flat section, a relatively straight tail portion of flat section, an intermediate stop portion of decreased width and increased thickness, said stop portion being laterally offset from said spring and tail portions, and a notched portion for weakening the wire between the tail portion of one contact and the spring portion of the next succeeding contact, and repeating said coining operation along a continuous wire to form contacts connected end to end.

18. In the manufacture of sockets for subminiature electronic devices, said sockets comprising a molded insulation base with passages receiving spring metal contacts of the single wire type, the method of making said contacts which includes coating with a corrosion resistant metal a round wire made of -a metal which is both resilient and highly conductive, cold coining and thereby flattening recurrent portions of the wire in order to work harden and thereby impart increased resilience to the contact without heat treatment of the wire, said coining operation being so performed as to also shape the contact to provide a convex spring portion of flat section, a relatively straight tail portion of flat section, and an intermediate stop portion of decreased width and increased thickness, said stop portion being laterally offset from said spring and tail portions, repeating said coining operation along a continuous Wire to form contacts connected end to end, and reeling the resulting continuous series of connected contacts, said contacts being coined and reeled with the spring portion foremost so that they may be unreeled with the tail portions foremost.

References Cited in the file of this patent UNITED STATES PATENTS 1,217,750 Greenfield Feb. 27, 1917 1,266,363 Wentz May 14, 1918 1,608,542 Witherow Nov. 30, 1926 2,329,769 Kinyon Sept. 21, 1943 2,480,059 Stickney Aug. 23, 1949 2,525,210 Del Camp Oct. 10, 1950 2,604,986 Berg July 29, 1952 2,613,432 Gilbert Oct. 14, 1952 2,614,274 Moore Oct. 21, 1952 2,670,530 Regnier Mar. 2, 1954 2,674,787 Lyon Apr. 13, 1954 2,700,206 Gilbert Ian. 25, 1955 2,742,686 Franz Apr. 24, 1956 2,748,452 Pierce June 5, 1956 2,778,097 Berg Jan. 22, 1957 

